deletions | additions       diff --git a/Table_ref_table_Johnson1_shows__.tex b/Table_ref_table_Johnson1_shows__.tex  index cfa3b99..0f33bde 100644  --- a/Table_ref_table_Johnson1_shows__.tex  +++ b/Table_ref_table_Johnson1_shows__.tex 
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Table.~\ref{table:Johnson1} shows the values for the Johnson Noise $^2 + ^2$ in units of Volts$^2$from a resistance value of $10K$ ohms, a temperature of $295.15$ Kelvin, a G1 of $600$, a G2 of $1000$, and we varied the f1 and f1 in order to change the bandwidth.   The values in \ref{table:Johnson1} are explained by the following equation:  $V_{\textrm{meter}} = (^2 + ^2) G_1 G_2 / (10 \textrm{Volts}) \textrm{ [mV]}$  where the factor of $10 \textrm{Volts}$ comes from the amplifier and the $^2 + ^2$ is the measured voltage from the multi-mete before the error has been subtracted.  --- \textbf{are these really Johnson noise voltages? I suspect from the rest of your paper that these might actually values for $^2 + ^2$ in units of Volts$^2$. Obviously, this is an important distinction, and not just a matter of being picky, b/c these are very different things physically and numerically would lead to very different results for your calculations!} ---- from a resistance value of $10K$ ohms, a temperature of $295.15$ Kelvin, a G1 of $600$, a G2 of $1000$, and we varied the f1 and f1 in order to change the bandwidth.